Abstract:

ABSTRACT
In this study, CNTs were produced using the floating catalyst CVD method by injection
of a catalyst solution into a high temperature zone of a furnace. The catalysts,
organometallic iron complexes, were dissolved in a hydrocarbon source (toluene) and
injected into the furnace to form CNTs. Various organometallic iron complexes were
used as catalysts for CNT synthesis. The catalysts used included: (a) mixtures of
ferrocene and M(CO)5
tBuCN (M = Mo and W), (b) mixtures of ferrocene and ferrocenyl
sulphide, (c) alkyl-ferrocenes, (d) ferrocenylacetanalides and (e) cyclopentadienyl
carbonyl iron complexes.
The reactions were carried out in flowing 5% H2 in Ar (100 ml/min) in the temperature
range of 700-1000 °C and at injection rates of between 0.2 and 3.3 ml/min, using various
catalyst concentrations (1-10 wt%).
The synthesis of multi-walled carbon nanotubes (MWCNTs) and carbon spheres (CSs)
was achieved with ferrocene (Fc), Mo(CO)5L (L = CO, tBuNC) and bimetallic catalyst
systems (Fc/M(CO)5
tBuNC; M = W or Mo). Ferrocene yielded CNTs and CSs while the
M(CO)5L complexes yielded little carbonaceous material. EDS and TEM analysis
revealed the formation of large particles of Mo/Fe alloys inside the tubes. It was observed
that the diameters of the CNTs catalyzed by Fc are smaller while the diameters of CSs are
larger relative to the diameters of CNTs and CSs produced by the bimetallic catalyst
systems. In all instances MWCNTs were produced, which contrasts with the single
walled CNTs produced by Fe/Mo supported heterogeneous catalyst systems.
MWCNTs were synthesised using toluene solutions of ferrocene and 1,1’-
bis(methylthio)ferrocene (ferrocenyl sulphide). It was found that the presence of large
amounts of sulphur in the reactant mixture deactivated the catalyst, therefore generating
only amorphous carbon while lower amounts of sulphur led to mixtures of MWCNTs and
carbon fibres. The product distribution and yield varied with the sulphur content. Thus,
when the sulphur content was high the yield was higher than when a low sulphur content
was used. More CNTs were formed when a low sulphur content was used with more
carbon spheres and amorphous carbon formed at a high sulphur content. HMTEM
analysis revealed that the MWCNTs were poorly graphitised. Comparison with data
using other sulphur sources (S8, thiophene) suggested that the proximity of the sulphur to
the Fe catalyst in the gas phase did play a role in the CNT formation.
Pyrolysis of (CpR)(CpR’)Fe (R and R’ = H, Me, Et and COMe) in toluene solution gave
multi-walled carbon nanotubes (MWCNTs) and carbon fibers (CFs). The effect of
pyrolysis temperature (800-1000 °C), catalyst concentration (5 and 10 wt% in toluene)
and solution injection rate (0.2 and 0.8 ml/min) on the type and yield of carbonaceous
product synthesised was investigated. Carbonaceous products formed included graphite
film (mostly at high temperature; 900-1000 °C), carbon nanotubes and carbon fibers. The
yield of carbonaceous materials increased with temperature and concentration. The
ferrocene ring substituents influenced both the CNT diameter and the carbon product
formed. The outer diameters of CNTs formed by dimethylferrocene were found to be
smaller (17-46 nm) than the diameters of CNTs formed by ferrocene (33-60 nm).
Diethylferrocene produced carbon spheres and amorphous carbon with no success in
forming CNTs.
Toluene solutions of 3-ferrocenyl-N,N-diisopropyl-3-oxo-propionamide
(diisopropylamide catalyst) were used to synthesize nitrogen containing MWCNTs. The
effect of pyrolysis temperature and solution feeding rate on the yield and morphology of
carbonaceous products were investigated. CNTs with bamboo structures were formed by
the diisopropyl catalyst at 800 °C, with outer tube diameters in the range of 28-74 nm.
Carbonaceous products formed include graphite film, which was formed mostly at high
temperatures, carbon nanotubes, carbon fibers and carbon spheres. A boron containing
iron catalyst {(1Z)-3-(diisopropylamino)-3-oxo-1-ferrocenylprop-1-ene-1-yl
difluoroborate} was used in an attempt to synthesize boron-doped CNTs. MWCNTs
which are not boron-doped were produced.
The organometallic complexes, CpFe(CO)2I was found to be inactive for CNT synthesis
and active for carbon spheres and fibers formation. CpFe(CO)2Me produced MWCNTs
with narrow diameter range (19-41 nm). The influence of temperature and catalysts
concentration was studied. High temperatures (900-1000 °C) produced more amorphous
carbon while low temperatures produced more CNTs. A low catalyst concentrations (5
wt.%) was used to form more CNTs than a high catalyst concentrations (10 wt.%).